Profinity IMAC Resins Selective Profinity IMAC Resins Provide Ultrahigh-Purity Recombinant

Transcription

Profinity IMAC Resins Selective Profinity IMAC Resins Provide Ultrahigh-Purity Recombinant
PROTEIN PURIFICATION
Profinity™ IMAC Resins
Unique open pore
structure facilitates
purification of large
MW proteins and
protein-protein
interaction studies
Excellent purity of
target proteins
Stability from pH 1 to 14
Compatibility with
denaturing agents,
detergents, and
reducing agents
Available in uncharged
and nickel-precharged
forms
Based on patented
UNOsphere™
technology
Selective Profinity IMAC Resins
Provide Ultrahigh-Purity Recombinant
His-Tagged Proteins
Introduction
Revolutionary advances in genomics and
proteomics have made possible the expression
of large amounts of proteins of interest, usually
in a tagged format, that allow standard
chromatography schemes to be used for their
purification. The most prevalent affinity tag by
far is the polyhistidine tag (His-tag). His-tagged
proteins are purified primarily by immobilized
metal affinity chromatography (IMAC).
Ni-charged Profinity IMAC resin, because of
its optimized ligand density and open pore
structure, interacts with high stringency with
recombinant His-tagged proteins of a wide
molecular weight range. This unique affinity
support is based on Bio-Rad’s innovative
UNOsphere resin* (Figure 1), which enables
Profinity IMAC resins to exhibit excellent flow
properties without compromising binding,
capacity, recovery, or purity.
Resin Characteristics
The Profinity IMAC bead is a 60 µm particle
derivatized with iminodiacetic acid (IDA), which
functions as the chelating ligand (Figure 2). The
chemical structure of IDA allows highly selective
binding of recombinant His-tagged proteins
when charged with Ni2+ or other transition
metals. As a result, target proteins can often be
purified close to homogeneity in a single step.
* US patent 6,423,666.
The selectivity of Profinity IMAC resin provides
specific purification of recombinant His-tagged
proteins rather than naturally occurring
His-containing proteins.
Characteristics like the polymeric nature,
optimized IDA ligand density, and open pore
structure of the Profinity IMAC bead result in
superb mechanical strength, high selectivity for
target proteins, low nonspecific binding, and the
ability to perform purifications at extremely fast
flow rates (see Specifications). These features
lend a number of benefits to the Profinity IMAC
resin and help distinguish it from other
commercial IMAC adsorbents.
Profinity IMAC resin is stable across the full pH
range of 1 to 14 and is compatible with all
reagents used in the purification of His-tagged
proteins, such as denaturing agents, detergents,
and reducing agents. The resin is available in two
forms: uncharged and precharged with Ni 2+.
Specifications
Table. Chemical compatibilities for binding of target
protein to Profinity IMAC Ni-charged resin.*
Functional ligand
IDA
Base bead
UNOsphere base matrix
Form
50% suspension in 20% EtOH,
precharged with Ni2+ or uncharged
Particle size
45–90 µm
Mean particle size
60 µm
Metal ion capacity
12–30 µmol Cu2+/ml
Dynamic binding capacity*
≥15 mg/ml
Recommended linear flow rate
≤600 cm/hr at 25°C
Maximum operating pressure**
7.5 bar (109 psi)
pH stability, uncharged resin***
(up to 200 hr)
1–14
Chemical compatibilities
See Table
Storage
4°C to ambient temperature
Shelf life in 20% EtOH
>1 year at ambient temperature
Operational temperature
4– 40°C
Autoclaving conditions
0.1 M sodium acetate at 120°C
for 30 min
* Binding capacity was determined by Q10% determination under the
following conditions (dynamic binding capacity will vary from protein
to protein):
Column volume
Sample
Flow rate
Loading buffer
Wash buffer
Elution buffer
1 ml (7 mm ID x 2.6 cm) column
1.8 mg/ml pure 32 kD His-tagged protein
1 ml/min loading
2 ml/min wash and elution
50 mM sodium phosphate, 300 mM
NaCl, 5 mM imidazole (pH 8.0)
Same as loading except 10 mM imidizole
Same as loading except 250 mM
imidazole
** Profinity IMAC resin was packed in a 1.1 x 30 cm column to a
bed height of 20 cm with 20 mM sodium phosphate buffer up to 3 bar
(43 psi). Flow rates were increased stepwise by 200 cm/hr and held
for 2 min at each step. The pressure-flow curve for Profinity IMAC
becomes nonlinear at pressures above 7.5 bar (109 psi).
***Ligand density and protein binding capacity are essentially unchanged
after resin is treated with pH 1–14 buffers or other solutions for up
to 200 hr.
Reagent
Concentration**
Buffer Reagents
Tris
HEPES
MOPS
Sodium or potassium
phosphate
50 mM
50 mM
50 mM
50 mM
Chelating Agents
EDTA, EGTA
0.1 mM
Sulfhydryl Reagents
β-Mercaptoethanol
DTT
TCEP
30 mM
5 mM
10 mM
Detergents
Nonionic detergents
(Triton, Tween, NP-40)
Cationic detergents (CTAB)
Zwitterionic detergents
(CHAPS, CHAPSO)
Anionic detergents (SDS,
Sarkosyl)
Denaturing Agents
Guanidine HCl
Urea
5%
1% (care must be taken to avoid
protein precipitation)
5%
1%
6-M
8-M
Other Additives
NaCl
2 M (at least 300 mM NaCl should be
included in buffers)
100 mM (HEPES or Tris should be used
to prevent precipitation)
10 mM (HEPES or Tris should be used
to prevent precipitation)
20%
20%
25 mM in wash buffer
500 mM for elution
80 mM
MgCl2
CaCl2
Glycerol
Ethanol
Imidazole
Citrate
* In order to determine the efficacy of protein binding and recovery,
tests were performed using a purified 75 kD protein in a static mode.
All tests were carried out using Micro Bio-Spin™ columns packed with
Profinity IMAC resin and eluted by centrifugation.
** Profinity IMAC binding capacities are unaffected with typical reagents
used for His-tagged protein purification, up to the concentrations given.
OH
H2C
CO
O
UNOsphere
Bead
N
Ni2+
H2C
CO
Fig. 1. Scanning electron micrograph of UNOsphere base bead.
Left, 1,500x magnification; right, 10,000x magnification.
© 2005 Bio-Rad Laboratories, Inc.
O
Fig. 2. Partial structure of Profinity IMAC resin. Illustration of
UNOsphere bead with coupled IDA functional ligand, shown charged
with Ni2+. Wavy lines indicate available binding sites.
Bulletin 3193
High Chemical Compatibility
The chemical stability of Profinity IMAC permits use of a
wide range of reagents. As shown in Figure 3, binding
capacity, purity, and recovery are unaffected even by
strong reducing agents, such as 5 mM DTT. The Table
lists the compatibility of Profinity IMAC resin (up to the
concentrations given) with some reagents that are
commonly used for recombinant protein purification.
–3
20
15
–2
10
–1
5
–0
0
0.0
0.0
0.2
0.5
1.0
[DTT], mM
[DTT], mM
0.5
1.0
2.0
5.0
2.0
5.0
unbound
Unbound
bound
Bound
B
0.2
Protein recovery, mg
Binding capacity,
mg/ml
A
1
Fig. 3. Performance of Profinity IMAC in the presence of strong
reducing agents. Purified protein (~2.5 mg) was loaded onto a Micro
Bio-Spin column packed with 100 µl of preequilibrated Profinity IMAC
resin. The binding buffer was 50 mM potassium phosphate, 300 mM
NaCl (pH 8.0) and the elution buffer was the binding buffer plus 500 mM
imidazole; the concentration of DTT in the buffers differed as indicated.
A, protein binding capacity and recovery.
, binding capacity;
• , protein recovery. B, SDS-PAGE analysis of duplicate samples.
Unbound and bound fractions are shown in alternating lanes.
Performance Benefits
Inherent structural characteristics along with the chemical
stability of Profinity IMAC resin provide a variety of benefits.
Purity, the most important benefit, results from the
stringency of interaction provided by the resin’s optimal
ligand density. Profinity IMAC specifically selects for
recombinant His-tagged proteins over naturally occurring
His-containing proteins, resulting in greater target protein
purity. A clear indication of the higher purity achieved by
Profinity IMAC resin over other commercial adsorbents is
shown in Figure 4. Using Quantity One® software, purity
levels of up to 93% were determined quantitatively for
samples from each resin.
© 2005 Bio-Rad Laboratories, Inc.
2
3
4
5
6
7
81%
78%
93%
89%
92%
8
Fig. 4. Purification of a putative aminopeptidase protein using
different IMAC resins. An insoluble 32 kD protein obtained from
Anabaena sp. strain PCC 7120 (courtesy of Dr Ray Stevens, University
of California, Berkeley, CA, USA) was expressed in E. coli and purified
under denaturing conditions. E. coli lysate was loaded onto Micro Bio-Spin
columns containing individual IMAC resins and purified. The binding
buffer was 50 mM potassium phosphate, 300 mM NaCl, 8 M urea (pH
8.0), and the elution buffer was binding buffer plus 250 mM imidazole.
To determine purity of the target protein, 3 µg of sample eluate from
each column was loaded and separated on a Criterion™ gel, stained with
Coomassie Blue, then quantitated using Quantity One software. Lanes 1
and 8, 10 µl Precision Plus Protein™ standards; lane 2, 3 µl crude lysate;
lane 3, Ni-charged, high-binding-capacity agarose-based resin from
supplier A (IDA ligand); lane 4, uncharged agarose-based resin from
supplier A (IDA ligand), charged with Ni2+; lane 5, Profinity IMAC Nicharged resin; lane 6, Ni-charged agarose-based resin from supplier B
(NTA ligand); lane 7, Co2+-charged tetradentate agarose (supplier C).
The purity obtained for each resin is indicated; arrow highlights result
obtained with Profinity IMAC.
Profinity IMAC and UNOsphere Technology
UNOsphere beads, on which Profinity IMAC resin is based,
were designed to achieve high productivity (grams drug or
target per operational hour per liter of support). UNOsphere
media may be run with solutions of different viscosity at
high flow rates, well within the pressure limits of lowpressure column and chromatography systems (Figure 5).
The dynamic binding capacities of Profinity IMAC and other
IMAC adsorbents were evaluated using a purified soluble
protein — NGG1P interacting factor 3 (NIF-3; 32 kD).
For evaluation, the A280 for the purified protein is first
measured. Dynamic binding capacity is determined by
continuously loading a sample of known concentration
to a column and monitoring the protein in the column
flow-through. When the quantity of the protein in the
flow-through exceeds 10% (Q10% or 10% breakthrough),
sample application stops. Next, the column was washed
and eluted. The amount of protein in mg that has been
applied up to a certain breakthrough point is a measure of
dynamic binding capacity of the IMAC resin. The broader
Bulletin 3193
250
200
150
100
19.0
18.5
18.0
17.5
17.0
50
16.5
1,200
0
0
200
400
600
800
1,000
Flow rate, cm/hr
Fig. 5. Shrink-swell test on Profinity IMAC resin. Common reagents
used in His-tagged protein purifications were run on a 1.1 x 30 cm
Amicon column packed with Profinity IMAC resin to a bed height of 20 cm.
System pressure and column bed height compression were recorded for
each flow rate. Flow rates were increased stepwise to 200 cm/hr and
held for 2 min at each step. All tests were performed on a BioLogic
DuoFlow Maximizer™ system. Yellow horizontal line indicates 43 psi
(3 bar), the maximum recommended operating pressure.
A
Excellent flow properties, high maximum operating
pressures, and high flow rates for fast cleaning, sanitizing,
and reequilibration are among the other benefits provided
by the polymeric nature and open pore structure of
Profinity IMAC resin. A good example of the productivity
of Profinity IMAC resin is the consistency with which
His-tagged dynamic binding capacity and selectivity at
various flow rates are maintained. Figure 7 demonstrates
the rapid binding kinetics of this resin, whether the column
is run at 150 cm/hr or at 600 cm/hr. Regardless of flow
B
1 3
Profinity IMAC
5
7
9
11 13 15
2.0
15.4 mg
1.5
Su
pp
lie
rB
19.5
20 mM sodium
phosphate
ddH2O
1 M NaOH
1 M NaCI
6 M guanidine HCI
8 M urea
20% EtOH
70% EtOH
Bed height, cm
Pressure, psi
300
the peak obtained during loading without product
breakthrough (see arrows in Figure 6A), the greater the
binding capacity is for that resin. The level of saturation of
the columns was determined by using a breakthrough
capacity measured at 10% (Q10%) and shows how the
capacity of Profinity IMAC resin outperforms products from
other suppliers (Figure 6).
Pr
e
Pr cisi
ot on
e P
Pu in s lus
re tan
Nl
d
F- ard
3
s
Pr
of
in
it
Su y IM
pp
AC
lie
rA
20.0
350
1.0
0.5
0.0
0
10
20
Supplier A
1 3
5
30
7
9
11 13 15
NIF-3
2.0
14.1 mg
Pressure, psi
1.5
1.0
0.5
0.0
0
10
20
1
Supplier B
3
5
7
30
9
11
13
15
2.0
3.4 mg
1.5
1.0
0.5
Fig. 6. Comparison of dynamic binding capacity for a His-tagged
NIF-3 protein. A, chromatograms. B, SDS-PAGE analysis. A sample
(1.8 mg/ml) of a purified 32 kD soluble protein, NIF-3, was continuously
loaded using a BioLogic DuoFlow™ system onto 1 ml columns containing
either Profinity IMAC (IDA ligand), an uncharged agarose-based resin
from supplier A (IDA ligand) that was charged with Ni2+ before
chromatography, or a Ni-charged agarose-based resin from supplier B
(NTA ligand) until Q10% breakthrough was achieved (black arrows indicate
time to breakthrough; values are protein loaded). A BioLogic DuoFlow
system was used to load the sample in 50 mM sodium phosphate,
300 mM NaCl, 5 mM imidazole (pH 8.0) at 1 ml/min. After 10%
breakthrough, the columns were washed in loading buffer with 10 mM
imidazole and eluted in loading buffer with 250 mM imidazole, all at
2 ml/min. For SDS-PAGE, a 10 µl aliquot of the sample load or eluate
was loaded per lane.
0.0
0
5
10
15
20
Run time, min
Bulletin 3193
© 2005 Bio-Rad Laboratories, Inc.
600 cm/hr
450 cm/hr
300 cm/hr
150 cm/hr
Pressure, psi
3
2
1
0
50
60
70
80
90
Run volume, ml
Fig. 7. Consistent binding capacity and selectivity for a His-tagged
protein at different flow rates. Crude E. coli lysate was loaded onto a
1 ml column (Amersham HR 5/5) preequilibrated with loading buffer
(50 mM potassium phosphate and 0.3 M NaCl, pH 8.0) using the
BioLogic DuoFlow system. The His-tagged protein was eluted with
buffer containing 50 mM potassium phosphate, 0.3 M NaCl, and
500 mM imidazole (pH 8.0). Elution was monitored at 280 nm.
Proteins eluted from the column were collected in 1 ml fractions.
rate, the target protein was still eluted in the same
number of fractions. Accordingly, the dynamic binding
capacity at 600 cm/hr was comparable to that obtained
when the column was run at 150 cm/hr at 20.3 and
21.8 mg/ml, respectively.
Flow vs. backpressure properties of Profinity IMAC resin
are also advantageous when regeneration, cleaning,
sanitization, and reequilibration are necessary (Figure 8).
200
Profinity IMAC
Supplier A
Supplier B
Pressure, psi
150
109 psi
100
40 psi
50
0
45 psi
0
400
800
1,200
1,600
2,000
2,400
2,800
Flow rate, cm/hr
Fig. 8. Comparison of maximum operating pressure for different
IMAC resins. The pressure values shown are the estimated maximum
operating pressures for each resin. Beyond these pressures, the column
beds are seriously compressed and damaged. Resins were converted
to a 50% (v/v) slurry in 20 mM sodium phosphate buffer and packed in
a 1.1 x 20 cm column to a bed height of 20 cm up to 43 psi (3 bar).
Flow rates were then increased stepwise by 200 cm/hr and held for
2 min at each step. The pressure-flow curve for Profinity IMAC resin
became nonlinear only at pressures above 109 psi (7.5 bar), the point
defined as the intersection of the two tangents on the pressure-flow curve.
Bulletin 3193
Repeated Cycling Stability Ensures
Reproducible Results
Profinity IMAC resin may be used many times without
affecting the quality or performance of this resin. To
demonstrate the durability of the material, Profinity IMAC
resin was subjected to 201 cycles of use — the sample
was loaded onto the column at the beginning of cycle
1 and after every interval of 50 wash cycles. The resulting
chromatogram (Figure 9) demonstrates that Profinity
IMAC resin, after repeated cycling, delivers consistent
and reproducible separation results.
4.0
3.0
Pressure, psi
4
2.0
1.0
0.0
0
10
20
Run time, min
30
40
Fig. 9. BioLogic DuoFlow system overlay report of a cycling study
performed using Profinity IMAC resin. A 1 ml column packed with
Profinity IMAC was subjected to 201 cycles of use. Sample (250 µl lysate
containing 3.51 mg of 75 kD recombinant His-tagged protein) was
loaded onto the column at cycle 1 and after every interval of 50 wash
cycles, which included the following steps:
Strip
50 mM EDTA, 50 mM sodium phosphate, 300 mM NaCl
(pH 7.5)
Clean
50 mM sodium acetate, 300 mM NaCl (pH 4.0)
Charge
100 mM NiSO4 (pH 4.0)
Clean
50 mM sodium acetate, 300 mM NaCl (pH 4.0)
Equilibrate 50 mM sodium phosphate, 300 mM NaCl (pH 8.0)
Sanitize
1.0 N NaOH (this step skipped before sample injection)
Recommended Columns for Packing
Profinity IMAC and Ni-charged IMAC resins are available
in both small and large packs, ranging from 10 ml to 1 L.
The resin is easy to pack and may be used in mediumpressure, gravity-flow, and spin columns. Bio-Rad offers
a variety of columns, including glass Econo-Column®
columns for gravity and low-pressure purifications,
Bio-Scale™ MT high-resolution columns for mediumpressure purifications, and empty Bio-Spin® and Micro
Bio-Spin columns for gravity and spin-column purifications.
Storage, Shelf Life, and Stability
Profinity IMAC resin is stable at room temperature and
across the pH range (1–14). The resin may be stored in
any of the following solutions:
1 N NaOH (up to 200 hr)
1% acetic acid and 0.12 M phosphoric acid,
pH 1.5 (up to 200 hr)
2% benzyl alcohol
20% ethanol
© 2005 Bio-Rad Laboratories, Inc.
Ordering Information
Catalog #
Description
Catalog #
Profinity IMAC
156-0121
156-0123
156-0125
156-0127
156-0131
156-0133
156-0135
156-0137
Resins*
Profinity IMAC Resin, 10 ml
Profinity IMAC Resin, 50 ml
Profinity IMAC Resin, 500 ml
Profinity IMAC Resin, 1 L
Profinity IMAC Ni-Charged Resin, 10 ml
Profinity IMAC Ni-Charged Resin, 25 ml
Profinity IMAC Ni-Charged Resin, 100 ml
Profinity IMAC Ni-Charged Resin, 500 ml
BioLogic DuoFlow QuadTec Systems, cont.
760-1136
BioLogic DuoFlow QuadTec Basic System, 100/120 V,
for Japan and Korea only
760-1138
BioLogic DuoFlow QuadTec Basic System, 220/240 V
760-1147
BioLogic DuoFlow QuadTec Standard System,
100/120 V, same as 760-1137 with BioFrac fraction
collector, diverter valve, two F1 racks
760-1146
BioLogic DuoFlow QuadTec Standard System,
100/120 V, for Japan and Korea only
760-1148
BioLogic DuoFlow QuadTec Standard System,
220/240 V
Related Products
Catalog #
Description
Bio-Scale Columns
751-0081
Bio-Scale MT2 Column, 7 x 52 mm
751-0083
Bio-Scale MT5 Column, 10 x 64 mm
751-0085
Bio-Scale MT10 Column, 12 x 88 mm
751-0087
Bio-Scale MT20 Column, 15 x 113 mm
Micro Bio-Spin Columns
732-6204
Micro Bio-Spin Chromatography Columns, empty, 100
731-1660
End Caps, for Micro Bio-Spin chromatography
columns, 1,000
Econo-Column Selection Packs**
737-6601
Econo-Column Selection Pack A, includes 7 columns,
1 each of 0.7 x 10, 20, and 30 cm; 1.5 x 30 and
50 cm; 2.5 x 20 and 50 cm
737-6607
Econo-Column Selection Pack B, includes 6 columns,
1 each of 1.0 x 20, 30, and 50 cm; 1.5 x 20, 30,
and 50 cm
BioLogic DuoFlow Systems
760-0037
BioLogic DuoFlow Basic System, 100/120 V, includes
Dell controller and monitor, USB Bitbus communicator,
F10 workstation, MX-1 mixer, 3-tray rack, AVR7-3
sample inject valve, fittings kit, UV detector with 5 mm
flow cell and 254/280 nm filters, conductivity monitor,
starter kit, UNO® Q1 column, instructions
760-0036
BioLogic DuoFlow Basic System, 100/120 V,
for Japan and Korea only
760-0038
BioLogic DuoFlow Basic System, 220/240 V
760-0047
BioLogic DuoFlow Standard System, 100/120 V,
same as 760-0037 with BioFrac™ fraction collector,
diverter valve, two F1 racks
760-0046
BioLogic DuoFlow Standard System, 100/120 V,
for Japan and Korea only
760-0048
BioLogic DuoFlow Standard System, 220/240 V
BioLogic DuoFlow QuadTec™ Systems
760-1137
BioLogic DuoFlow QuadTec Basic System, 100/120 V,
includes Dell controller and monitor, USB Bitbus
communicator, F10 workstation, MX-1 mixer, 3-tray
rack, AVR7-3 sample inject valve, fittings kit, QuadTec
UV/Vis detector with 3 mm PEEK flow cell, instrument
control module (ICM), system cables 25 and 26
(RS-232 and ICM power), conductivity monitor,
starter kit, UNO Q1 column, instructions
Description
BioLogic DuoFlow Maximizer Systems
760-2237
BioLogic DuoFlow Maximizer 20 System, 100/120 V,
includes Maximizer valve unit, Maximizer mixer, pH
monitor, Dell controller and monitor, USB Bitbus
communicator, F10 workstation, MX-1 mixer, 3-tray
rack, AVR7-3 sample injection valve, fittings kit, UV
detector with 5 mm flow cell and 254/280 nm filters,
conductivity monitor, starter kit, UNO Q1 column,
BioFrac fraction collector, diverter valve, two F1 racks,
instructions
760-2236
BioLogic DuoFlow Maximizer 20 System, 100/120 V,
for Japan and Korea only
760-2238
BioLogic DuoFlow Maximizer 20 System, 220/240 V
760-2247
BioLogic DuoFlow Maximizer 80 System, 100/120 V,
same as 760-2237 with F40 workstation replacing F10
workstation
760-2246
BioLogic DuoFlow Maximizer 80 System, 100/120 V,
for Japan and Korea only
760-2248
BioLogic DuoFlow Maximizer 80 System, 220/240 V
BioLogic DuoFlow Pathfinder™ Systems
760-2257
BioLogic DuoFlow Pathfinder 20 System, 100/120 V,
includes Maximizer valve unit, Maximizer mixer, pH
monitor, Dell controller and monitor, USB Bitbus
communicator, F10 workstation, MX-1 mixer, 3-tray
rack, AVR7-3 sample inject valve, fittings kit, QuadTec
UV/Vis detector with 3 mm PEEK flow cell, system
cable 25 (RS-232), conductivity monitor, starter kit,
UNO Q1 column, BioFrac fraction collector, diverter
valve, two F1 racks, instructions
760-2256
BioLogic DuoFlow Pathfinder 20 System, 100/120 V,
for Japan and Korea only
760-2258
BioLogic DuoFlow Pathfinder 20 System, 220/240 V
760-2267
BioLogic DuoFlow Pathfinder 80 System, 100/120 V,
same as 760-2257 with F40 workstation replacing F10
workstation
760-2266
BioLogic DuoFlow Pathfinder 80 System, 100/120 V,
for Japan and Korea only
760-2268
BioLogic DuoFlow Pathfinder 80 System, 220/240 V
* Larger volumes for industrial applications are available on request.
** Many more Econo-Column chromatography columns are available.
The complete selection can be found in the current Life Science
Research Products catalog.
Amicon is a trademark of Amicon Corporation. Coomassie is a trademark
of BASF Aktiengesellschaft. Dell is a trademark of Dell Inc. Triton is a
trademark of Union Carbide. Tween is a trademark of ICI Americas Inc.
Bio-Rad
Laboratories, Inc.
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Life Science
Group
Bulletin 3193
US/EG
Rev A
04-0775
0305
Sig 1204